Biometric authentication apparatus and biometric authentication method

ABSTRACT

The present invention is a biometric authentication apparatus comprising, a fingertip sensor mounted on a tip placement surface of a tip placement section for placing a tip of a finger cushion said fingertip sensor detecting displacement of an arrangement position of a finger on the tip placement surface of the tip placement section, wherein the biometric authentication apparatus detects the displacement of a position of the tip of the finger cushion.

CROSS-REFERENCES

The present application is a Continuation application of U.S. patentapplication Ser. No. 13/824,166 filed on Mar. 15, 2013, which is aNational Stage entry of international application PCT/JP2011/071362,filed Sep. 20, 2011, which claims priority rights based on a JapanesePatent Application 2010-216378 filed on Sep. 28, 2010. The disclosuresof all of which are incorporated in their entirety by reference herein.

TECHNICAL FIELD

The present invention relates to a biometric authentication apparatusand a biometric authentication method.

BACKGROUND ART

The biometric authentication technology of authenticating a person usingan image of a finger is known as a technique of collating a pattern ofan epidermis such as a fingerprint of a finger, and a pattern of a bloodvessel with previously registered information.

In the biometric authentication apparatus employing this technology,correct authentication cannot be obtained, the personal authenticationis rejected as NG (No Good), and much time for the authentication isrequired unless the fingerprint etc., being a target of authentication,is imaged in a situation in which the fingerprint etc. is arranged at acorrect position in the biometric authentication apparatus.

Thereupon, the individual authentication apparatus by a finger vein thataims for enabling a user to easily recognize a position for placing thefinger is described in Patent literature 1.

The individual authentication apparatus described in the Patentliterature 1 notifies a user of the position for placing the finger bylighting the position, and reduces displacement of the finger by makingthe user press a data loading switch while adjusting the finger to alight emission unit.

CITATION LIST Patent Literature

PTL 1: JP-P2005-323892A

SUMMARY OF INVENTION Technical Problem

However, the invention disclosed in the above-described Patentliterature 1 has the following problems.

The invention of the Patent literature 1, which adjusts the finger tothe light emission unit, has a problem that a utilizer cannot recognizethe position of the finger even though the finger is placed in asituation of being rotated, and even though the finger is placed in asituation of being displaced to a left and a right.

Thereupon, the present invention has been accomplished in considerationof the above-mentioned problems, and an object of the present inventionis to provide a biometric authentication apparatus and a biometricauthentication method that detect position displacement of a target ofthe imaging that occurs in a case in which the utilizer places thefinger in a situation of being rotated, and places the finger in asituation of being displaced to a left and a right.

Solution to Problem

The present invention is a biometric authentication apparatuscomprising, a fingertip sensor mounted on a tip placement surface of atip placement section for placing a tip of a finger cushion saidfingertip sensor detecting displacement of an arrangement position of afinger on the tip placement surface of the tip placement section,wherein said biometric authentication apparatus detects the displacementof a position of the tip of the finger cushion.

The present invention is biometric authentication method comprising:detecting displacement of a position of a e tip of a finger cushion by afingertip sensor that is mounted on a tip placement surface of a tipplacement section for placing the tip of the finger cushion; andteaching a utilizer the displacement of the arrangement position of thefinger.

The present invention is a program for causing a computer to execute: adetection process of receiving a signal coming from a fingertip sensorfor detecting displacement of a an arrangement position of a finger,said fingertip sensor mounted in a tip placement surface of a tipplacement section for placing a tip of a finger cushion, and detectingthe displacement of a position of the tip of the finger cushion; and ateaching process of teaching a utilizer the displacement of thearrangement position of the finger.

Advantageous Effect of Invention

The present invention makes it possible to detect position displacementof a target of the imaging that occurs in a case in which the utilizerplaces the finger in a situation of being rotated, and places the fingerin a situation of being displaced to a left and a right.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram of the individual authentication apparatus ina first exemplary embodiment.

FIG. 2 is a view for explaining a sensor to be mounted in a tipplacement section 1.

FIG. 3 is a view illustrating one example of guidance by a guidance lamp14.

FIG. 4 is an operational flowchart of an operation in the firstexemplary embodiment.

FIG. 5 is a block diagram of a second exemplary embodiment.

FIG. 6 is an appearance view of the individual authentication apparatusof an example 1.

FIG. 7 is a view for explaining a wiring pattern of a sensor 12 and anoutput thereof in the example 1.

DESCRIPTION OF EMBODIMENTS First Exemplary Embodiment

The biometric authentication apparatus relating to the first exemplaryembodiment, which is an apparatus that simultaneously images thefingerprint of the finger of the user and the vein existing inside it,can be utilized, for example, as the individual authentication apparatus(biometric authentication apparatus) that authenticates the person byutilizing the imaged fingerprint and vein of the finger. The finger tobe imaged could be any finger (a thumb, an index finger, a middlefinger, a ring finger, and a little finger); however, herein, the caseof imaging the fingerprint and the vein of the index finger(hereinafter, simply, referred to as a “finger”) is exemplified forexplanation.

FIG. 1 is a block diagram of the individual authentication apparatus inthis exemplary embodiment. As shown in FIG. 1, the individualauthentication apparatus in the first exemplary embodiment includes atip placement section 1 for placing a tip of a finger cushion of afinger FG, a base placement section 2 for placing a base of the fingercushion of the finger FG, a spot light generation light source 3, animaging unit 4, an imaging control unit 5, an image processing unit 6, acollation unit 7, and a display unit 8.

The tip placement section 1, as shown in FIG. 2, includes a tipplacement surface 11 on which the tip of the finger cushion is placed,and a sensor 12 for detecting an arrangement position of the finger froman electric change.

The tip placement surface 11 is a surface that the tip of the fingercushion contacts, and has such a shape of a concave surface that getsitself to the tip of the finger cushion of the finger FG. The sensor 12,which is arranged inside the tip placement surface 11, detects rotationand position displacement in a left direction and a right direction (adirection vertical to a line connecting the tip placement section 1 andthe base placement section 2) of the finger FG, being a target of theimaging. And, the sensor 12 supplies an output of the sensor 12 to adetection unit 13 mounted inside the individual authenticationapparatus.

With regard to a method of detecting the position displacement of thefinger by the detection unit 13, a wiring pattern, of which an output ischanged responding to a position in which the finger contacts the tipplacement surface 11, and a switch, which is switched on when the fingercontacts the tip placement surface 11, can be employed as the sensor 12to detect the position displacement from the above signal.

The guidance lamp 14 guides the position displacement of the fingerbased on a detection result of the detection unit 13. For example, basedon the detection result of the detection unit 13, the guidance lamp 14teaches the user the position of the tip placement surface 11 in whichthe finger is located, namely the position in which the fingertip shouldbe arranged by lighting and flashing the lamp. FIG. 3 shows one exampleof the guidance by the guidance lamp 14. In FIG. 3, the guidance exampleby the two guidance lamp 14 is shown, and when the finger FG iscorrectly arranged on the tip placement surface 11, both of the twoguidance lamps 14 are lighted. On the other hand, when the finger FG isarranged in the left side of the tip placement surface 11, namely isdisplaced to the left side from the correct position, only the left-sideguidance lamp 14 is flashed, and when the finger FG is arranged in theright side of the tip placement surface 11, namely is displaced to theright side from the correct position, only the right-side guidance lamp14 is flashed. In such a manner, the guidance lamp 14 guides theposition in which the finger FG is arranged to the correct position.

The spot light generation light source 3, which is mounted at a positionin which a contact with the finger FG is not made, radiates parallellight to a fingerprint portion in a spot manner at an almost uniformluminance in terms of an entirety of the fingerprint portion between adistal interphalangeal joint (first knuckle joint) of the finger FG andthe fingertip. Herein, the so-called parallel light is light that isuniformly radiated at an almost identical angle to the fingerprintportion (the surface of the fingerprint portion). Further, the spotlight generation light source 3 preferably radiates light from onedirection because it is desired that shadow due to irregularities of theskin surface is generated as much as possible in order to image thefingerprint, being the irregularities of the skin surface of the fingerFG.

Preferably, the spot light of the spot light generation light source 3is light having a wavelength component of a wavelength ranging from 1000nm to 600 nm or so that is known as light easily permeating a bodytissue except for bones of human being, and the spot light generationlight source is comprised of, for example, a halogen lamp, a xenon lampand a lens, or LED etc. having an emission feature within thecorresponding wave length to which a lens has been attached.

The imaging unit 4 is configured of an image sensor such as CCD andCMOS, a control system, a lens optical system for focusing a fingerprintimage and a blood vessel image of the finger in the image sensor, andthe like. Herein, the imaging unit 4 images the fingerprint of thefingerprint portion between the distal interphalangeal joint (firstknuckle joint) of the finger FG and the fingertip with reflected lightto the fingerprint portion between the distal interphalangeal joint(first knuckle joint) of the finger FG and the fingertip due to radiatedlight coming from the spot light generation light source 3 taken as mainlight, and images the blood vessel with scattered light that leaks (isradiated) from the epidermis between the distal interphalangeal joint(first knuckle joint) and a proximal interphalangeal joint (secondknuckle joint) as a result of the fact that the light radiated to thefingerprint portion from the spot light generation light source 3 isscattered inside the finger FG and is propagated. Additionally, thefingerprint and the blood vessel are simultaneously imaged by theimaging unit 4. Additionally, the imaging unit 4 is mounted at aposition in which a contact with the finger FG is not made, similarly tothe spot light generation light source 3.

The imaging control unit 5 controls the imaging of the imaging unit 4,prepares the signal of the imaging unit 4 as data, and sends thefingerprint image and the blood vessel image to the image processingunit 6.

The image processing unit 6 extracts a center of the fingerprint fromthe image data of the fingerprint acquired from the imaging control unit5 to measure the displacement of the center of the finger FG from anexternal shape. And, the image processing unit 6 detects a rotationalquantity of the finger, displays correct position modificationinformation of the finger on the display unit 8 by the above rotationalquantity, and urges an authenticatee who receives the authentication tocorrectly modify the position of the finger. In addition, the imageprocessing unit 6 extracts an image feature of the fingerprint and thefinger blood vessel from the data of the image taken by the imaging unit4 after correctly modifying the position of the finger FG, and outputsdata of the extracted image feature to the collation unit 7.

The collation unit 7 in which the image feature of the fingerprint andthe finger blood vessel of the authenticatee has been stored collatesthe stored image feature of the fingerprint and the finger blood vesselof the authenticatee with the image feature of the fingerprint and thefinger blood vessel coming from the image processing unit 6, andperforms the authentication.

Additionally, the image processing unit 6 or the collation unit 7 mayrecord a plurality of pieces of reference data (the image feature of thefingerprint and the finger blood vessel) registered by previouslyrotating the finger of the authenticatee, select data having therotational quantity of which the image feature approximates the imagefeature of the fingerprint and the finger blood vessel extracted by theimage processing unit 6, and perform the collation with the imagefeature of the fingerprint and the finger blood vessel thereof.

Next, an operation of the imaging of the fingerprint and the bloodvessel, and the collation in the first exemplary embodiment will beexplained.

FIG. 4 is an operational flowchart of the imaging of the fingerprint andthe blood vessel, and the collation in the first exemplary embodiment.

At first, the finger FG is arranged on the tip placement section 1 andthe base placement section 2 (Step 100).

The sensor 12 performs the outputting responding to the position of thetip of the finger cushion of the arranged finger FG (Step 101).

The detection unit 13, upon receipt of the output of the sensor 12,detects where the finger is arranged in terms of the position of the tipplacement surface 11. The detection unit 13 teaches that the finger FGhas been correctly arranged (Step 103) by lighting both of the twoguidance lamps 14 when the detected position is a correct arrangementposition (Step 102).

On the other hand, the detection unit 13 teaches that the finger FG hasbeen displaced to the side in which the guidance lamp 14 flashes byflashing the guidance lamp 14 existing in the displacement directionwith the correct arrangement position at a center, out of the twoguidance lamps 14, (Step 104) when the detected position is not acorrect arrangement position (Step 102).

When it is detected that the finger FG has been correctly arranged, thespot light generation light source 3 radiates the parallel light to anentirety of the fingerprint portion above the distal interphalangealjoint (first knuckle joint) of the finger FG at a uniform luminance andin a spot manner (Step 105).

The imaging unit 4 images, by the imaging control unit 5, the part thatincludes the fingerprint ranging from the proximal interphalangeal joint(second knuckle joint) to the fingertip and the blood vessel of thefinger FG (Step 106). Herein, the fingerprint portion between the distalinterphalangeal joint (first knuckle joint) of the finger FG and thefingertip is imaged with the reflected light due to the radiated lighttaken as main light. On the other hand, comparatively large bloodvessels exist between the distal interphalangeal joint (first knucklejoint) and the proximal interphalangeal joint (second knuckle joint) ofthe finger FG and just under the skin in the neighborhood of the knucklejoints. In this portion, light radiated to the fingerprint portion bythe spot light generation light source 3 is scattered within the finger,is propagated within the finger, and is radiated from the epidermis, andthus the blood vessel is imaged. Additionally, the fingerprint and theblood vessel are simultaneously imaged.

The imaging control unit 5 prepares the signal of the imaging unit 4 asdata, and outputs the fingerprint image and the blood vessel image tothe image processing unit 6 (Step 107).

The image processing unit 6 extracts the image feature of thefingerprint and the finger blood vessel from the data of the image takenby the imaging unit 4, and outputs data of the extracted image featureto the collation unit 7 (Step 108).

The collation unit 7 performs the collation based on the image featureof the fingerprint and the finger blood vessel coming from the imageprocessing unit 6 (Step 109).

As explained above, the first exemplary embodiment exhibits an effectdescribed below.

The first exemplary embodiment makes it possible to detect the positiondisplacement of the finger that exerts an influence on the image of theauthentication part of the finger, in particular, the rotation of thefinger caused by the position displacement of the fingertip, and theposition displacement in the left direction and the right direction, andto take the correct image necessary for the authentication.

In addition, the first exemplary embodiment radiates the parallel lightto the fingerprint portion of the finger in a spot manner,simultaneously takes the blood vessel images by the scattered light thatis scattered inside the finger, is propagated from the fingerprintportion, and leaks out (is radiated) from the epidermis between thedistal interphalangeal joint (first knuckle joint) and the proximalinterphalangeal joint (second knuckle joint), and the fingerprint imageby the parallel light radiated to the fingerprint portion of the fingerin a spot manner with one imaging unit, whereby an effect lies in apoint of being able to perform the collation process (individualauthentication) for a short time with a simplified structure.

Further, the parallel light to be radiated to the fingerprint portion ina spot manner allows the shadow to be easily generated due to theirregularities of the fingerprint, and the scattered light allows thefingerprint image having an excellent contrast to be obtained.

Second Exemplary Embodiment

The second exemplary embodiment will be explained.

The second exemplary embodiment is provided with a sensor for detectingthat the base of the finger has been arranged on the base placementsection 2 for placing the base of the finger cushion in addition to thefirst exemplary embodiment, and an example will be explained of startingthe imaging when the base of the finger has been arranged on the baseplacement section 2 and yet the tip of the finger has been correctlyarranged.

FIG. 5 is a block diagram of the second exemplary embodiment.Additionally, identical codes are affixed to the parts similar to thefirst exemplary embodiment, so the detailed explanation is omitted.

As shown in FIG. 5, the base placement section 2 is provided with asensor 21. The sensor 21 is a pressure sensor of which a switch isswitched on when the base of the finger contacts the base placementsection 2.

A detection unit 23 inputs an output of the sensor 12 and an output ofthe sensor 21. And, the detection unit 23 instructs the imaging controlunit 5 to start the imaging when the sensor 12 detects that the tip ofthe finger FG has been correctly arranged and the base of the finger FGhas been arranged on the base placement section 2.

In accordance with the second exemplary embodiment, there is nopossibility that the imaging is performed in a situation in which onlytip of the finger has been arranged on the tip placement section 1because it is detected that the base of the finger has been arranged onthe base placement section 2, whereby a failure of the imaging of thefingerprint and the blood vessel of the finger necessary for theauthentication can be prevented, in addition to the effect of the firstexemplary embodiment.

Example 1

Next, a specific example 1 of the present invention will be explained.

FIG. 6 is an appearance view of the individual authentication apparatusof the example 1.

As shown in FIG. 6, the individual authentication apparatus of theexample 1 includes a tip placement section 1 for placing the tip of thefinger cushion of the finger FG and a base placement section 2 forplacing the base of the finger cushion of the finger FG, and includes asensor 12 for detecting the arrangement position of the finger from anelectric change insides a tip placement surface 11 of the tip placementsection 1. Further, the individual authentication apparatus includes asensor 21, being a pressure sensor, insides the base placement section2.

One example of the sensor 12 to be mounted insides the tip placementsurface 11 is shown in FIG. 7.

The sensor 12 is a sensor having a wiring pattern as shown in FIG. 7 inwhich the flowing current is changed responding to the position of thefinger that contacts the sensor 12 and an output thereof is alsochanged. With the wiring pattern show in FIG. 7, a value of an output tothe detection unit 23 becomes maximized when the finger is arrangedbetween a position A and a position B, and an output of the sensorbecomes one third of the maximum value when the finger is arranged inthe neighborhood of the position A and when the finger is arranged inthe neighborhood of the position B.

The detection unit 23, upon receipt of such an output of the sensor 12,detects the position in which the finger has been arranged, and lightsor flashes the guidance lamp 14. For example, the detection unit 23lights both of the two guidance lamps 14 when the finger has beencorrectly arranged on the tip placement surface 11. On the other hand,the detection unit 23 flashes only the left-side guidance lamp 14 whenthe finger has been arranged in the left side of the tip placementsurface 11, namely the finger has been displaced to the left side fromthe correct position, and the detection unit 23 flashes only theright-side guidance lamp 14 when the finger has been arranged in theright side of the tip placement surface 11, namely the finger has beendisplaced to the right side from the correct position. In such a manner,the detection unit 23 guides the position in which the finger isarranged to the correct position.

On the other hand, when the base of the finger is arranged in asituation of having a contact with the base placement section 2, thecontact of the base of the finger with the base placement section 2 isdetected by the pressure sensor of the sensor 21 mounted on the baseplacement section 2, and this detection result is outputted to thedetection unit 23.

The detection unit 23 instructs the imaging control unit 5 to start theimaging when an output of the sensor 12 and an output of the sensor 21are inputted, an output of the sensor 12 indicates that the tip of thefinger has been arranged at a correct position and yet the contact ofthe base of the finger with the base placement section 2 has beendetected due to an output of the sensor 21.

Additionally, as apparent from the above-described explanation, eachunit can be configured with hardware; however, it can be also realizedwith a computer program. In this case, functions and operations similarto those of the above-described embodiments and example are realizedwith a processor that operates under a program stored in a programmemory.

Further, the content of the above-mentioned exemplary embodiments can beexpressed as follows.

Supplementary Note 1

A biometric authentication apparatus comprising,

a fingertip sensor mounted on a tip placement surface of a tip placementsection for placing a tip of a finger cushion said fingertip sensordetecting displacement of an arrangement position of a finger on the tipplacement surface of the tip placement section,

wherein said biometric authentication apparatus detects the displacementof a position of the tip of the finger cushion.

Supplementary Note 2

The biometric authentication apparatus according to Supplementary note1, comprising a guidance means that teaches the displacement of thearrangement position of the finger based on a detection result of saidfingertip sensor.

Supplementary Note 3

The biometric authentication apparatus according to

Supplementary note 1 or Supplementary note 2, wherein said fingertipsensor is a sensor of which an output is changed responding to thearrangement position of the finger.

Supplementary Note 4

The biometric authentication apparatus according to one of Supplementarynote 1 to Supplementary note 3, comprising

a finger base sensor mounted on a base placement section for placing abase of a finger cushion said finger base sensor detecting that a baseof the finger has been arranged on said base placement section,

wherein said biometric authentication apparatus starts imaging of aportion, being a target of authentication, when it is detected by saidfinger base sensor that the base of the finger has been arranged on saidbase placement section and yet the tip of the finger has been correctlyarranged by said fingertip sensor.

Supplementary Note 5

A biometric authentication method comprising:

detecting displacement of a position of a e tip of a finger cushion by afingertip sensor that is mounted on a tip placement surface of a tipplacement section for placing the tip of the finger cushion; and

teaching a utilizer the displacement of the arrangement position of thefinger.

Supplementary Note 6

The biometric authentication method according to Supplementary note 5,wherein said fingertip sensor detects the arrangement position of thefinger from a change in an electric output.

Supplementary Note 7

The biometric authentication method according to Supplementary note 5 orSupplementary note 6, comprising:

starting imaging of a portion, being a target of authentication, when itis detected by a finger base sensor that a base of the finger has beenarranged on a base placement section for placing the base of the fingercushion and yet the tip of the finger has been correctly arranged bysaid fingertip sensor, said finger base sensor mounted on said baseplacement section.

Supplementary Note 8

A program for causing a computer to execute:

a detection process of receiving a signal coming from a fingertip sensorfor detecting displacement of a an arrangement position of a finger,said fingertip sensor mounted in a tip placement surface of a tipplacement section for placing a tip of a finger cushion, and detectingthe displacement of a position of the tip of the finger cushion; and

a teaching process of teaching a utilizer the displacement of thearrangement position of the finger.

Supplementary Note 9

The program according to Supplementary note 8, wherein said detectionprocess is a process of detecting the arrangement position of the fingerfrom a change in an electric output of said fingertip sensor.

Supplementary Note 10

The program according to Supplementary note 8 or Supplementary note 9,causing the computer to executed an imaging process of imaging aportion, being a target of authentication, when from a signal comingfrom a finger base sensor for detecting that a base of finger has beenarranged, said finger base sensor mounted in a base placement sectionfor placing the base of the finger cushion, it is detected by saidfinger base sensor the base of the finger has been arranged on said baseplacement section and yet the tip of the finger has been correctlyarranged by said fingertip sensor.

Above, although the present invention has been particularly describedwith reference to the preferred embodiments and the examples, it shouldbe readily apparent to those of ordinary skill in the art that thepresent invention is not always limited to the above-mentionedembodiments and the examples, and changes and modifications in the formand details may be made without departing from the spirit and scope ofthe invention.

This application is based upon and Supplementary notes the benefit ofpriority from Japanese patent application No. 2010-216378, filed on Sep.28, 2010, the disclosure of which is incorporated herein in its entiretyby reference.

REFERENCE SIGNS LIST

1 tip placement section

2 base placement section

3 spot light generation light source

4 imaging unit

5 imaging control unit

6 image processing unit

7 collation unit

8 display unit

11 tip placement surface

12 and 21 sensors

13 and 23 detection units

14 guidance lamp

The invention claimed is:
 1. A biometric detection apparatus comprising:a fingertip sensor to detect placement of the fingertip; a finger basesensor to detect placement of the base of the finger, a processorcoupled to a memory, wherein the processor performs operations, theoperations comprising detecting the placement of the fingertip and theplacement of the base of the finger based on outputs from the fingertipsensor and the finger base sensor.
 2. The biometric detection apparatusaccording to claim 1, further comprising a guidance device configured toperform guidance of the placement of the finger based on a detectionresult of the processor.
 3. The biometric detection apparatus accordingto claim 1, wherein the fingertip sensor is a sensor of which the outputis changed responding to a position of the placement of the fingertip,and the operations further comprising detecting that the position of theplacement of the fingertip is correct based on the output from thefingertip sensor.
 4. The biometric detection apparatus according toclaim 1, wherein the operations further comprising: controlling animaging device to capture an image of a part of the finger, being atarget of authentication, when the placement of the fingertip and theplacement of the base of the finger are detected by the processor.
 5. Abiometric detection method using a processor, comprising: detectingplacement of the fingertip and placement of the base of the finger basedon outputs from a fingertip sensor and a finger base sensor, wherein thefingertip sensor detects placement of the fingertip and the finger basesensor detects placement of the base of the finger.
 6. The biometricdetection method according to claim 5, further comprising; performingguidance of the placement of the finger based on the detection result.7. The biometric authentication method according to claim 5, wherein thefingertip sensor is a sensor of which the output is changed respondingto a position of the placement of the fingertip, and the biometricauthentication method further comprising detecting that the position ofthe placement of the fingertip is correct based on the output from thefingertip sensor.
 8. The biometric detection method according to claim5, further comprising: controlling an imaging device to capture an imageof a part of the finger, being a target of authentication, when theplacement of the fingertip and the placement of the base of the fingerare detected.
 9. A non-transitory computer readable storage mediumstoring a program for causing a biometric detection apparatus including:a processor to perform operations, a fingertip sensor to detectplacement of the fingertip, and a finger base sensor to detect placementof the base finger; wherein the program causes the processor to executeprocess of detecting the placement of the fingertip and the placement ofthe base of the finger based on outputs from the fingertip sensor andthe finger base sensor.
 10. The non-transitory computer readable storagemedium according to claim 9, wherein the program causes the processor toexecute process of performing guidance of the placement of the fingerbased on the detection result.
 11. The non-transitory computer readablestorage medium according to claim 9, wherein the fingertip sensor is asensor of which the output is changed responding position of theplacement of the fingertip, and wherein the program causes the processorto execute process of detecting that the position of the placement ofthe fingertip is correct based on the output from the fingertip sensor.12. The non-transitory computer readable storage medium according toclaim 9, wherein the program causes the processor to execute process ofcontrolling an imaging device to capture an image of a part of thefinger, being a target of authentication, when the placement of thefingertip and placement of the base of the finger are detected.